DE112022003043T5 - OPTICAL MODULE AND OPTICAL CONNECTION CABLE - Google Patents

Abstract

An optical module includes a substrate, an optical component and an optical coupling module. The substrate includes a glass fabric formed from glass threads that serve as a weft and a warp. An outer edge of the substrate has a rectangular shape defined by a pair of first side surfaces in a predetermined direction and a pair of second side surfaces in a direction perpendicular to the predetermined direction. The optical coupling module is optically coupled to the optical component. The weft thread is inclined with respect to the first side surfaces and the second side surfaces. The warp thread is inclined with respect to the first side surfaces and the second side surfaces. A depression is formed in the substrate. At least a portion of the optical coupling module is housed in the recess. A side surface of the recess includes an inclined region that is inclined with respect to an extension direction of the weft thread and an extension direction of the warp thread.

Description

Technical area

The present disclosure relates to an optical module and an optical connection cable. The present application claims priority based on the Japanese Patent Application No. 2021 - 128994 , filed August 5, 2021, all of the content described in the application being incorporated herein by reference.

background

Patent Literature 1 discloses an optical component as an example of an optical module, which includes a substrate having an optical component mounted thereon and an optical coupling module optically coupled to the optical component. In the optical module, light emitted from optical fibers held by the optical coupling module impinges on the optical component mounted on the substrate via the optical coupling module.

Citation list

Patent literature

[Patent Literature 1] Japanese Unexamined Patent Publication No. 2019-082508

Summary of the invention

An optical module of the present disclosure includes a substrate, an optical component, and an optical coupling module. The substrate includes a glass fabric inside, which is formed from glass threads that serve as a weft thread and a warp thread. An outer edge of the substrate, viewed in a thickness direction, has a rectangular shape defined by a pair of first side surfaces in a predetermined direction and a pair of second side surfaces in a direction perpendicular to the predetermined direction. The optical component is mounted on the substrate. The optical coupling module is designed to be optically coupled to the optical component. The weft thread is inclined with respect to the first side surfaces and the second side surfaces as viewed in the thickness direction of the substrate. The warp thread is inclined with respect to the first side surfaces and the second side surfaces as viewed in the thickness direction of the substrate. A depression recessed from a first major surface of the substrate toward a second major surface of the substrate to include a bottom portion is formed in the substrate. At least a portion of the optical coupling module is housed in the recess. A side surface of the recess includes an inclined region that is inclined with respect to an extension direction of the weft thread and an extension direction of the warp thread, as viewed in the thickness direction of the substrate.

An optical module of the present disclosure includes a substrate, an optical component, and an optical coupling module. The substrate includes a glass fabric inside, which is formed from glass threads that serve as a weft thread and a warp thread. An outer edge of the substrate, viewed in a thickness direction, has a rectangular shape defined by a pair of first side surfaces in a predetermined direction and a pair of second side surfaces in a direction perpendicular to the predetermined direction. The optical component is mounted on the substrate. The optical coupling module is designed to be optically coupled to the optical component. The weft thread extends along the first side surfaces as viewed in the thickness direction of the substrate. The warp thread extends along the second side surfaces as viewed in the thickness direction of the substrate. A depression recessed from a first major surface of the substrate toward a second major surface of the substrate to include a bottom portion is formed in the substrate. At least a portion of the optical coupling module is housed in the recess. A side surface of the recess includes an inclined region that is inclined in the thickness direction of the substrate with respect to an extension direction of the final thread and an extension direction of the warp thread.

Brief description of the drawings

• 1 is a perspective view illustrating an end portion of an optical connector cable according to an embodiment.
• 2 is a perspective view showing the end portion of the optical connection cable from which a protective member is removed.
• 3 is a top view of an optical module seen from above a first major surface of a substrate.
• 4 is a top view of the optical module seen from over a second major surface of the substrate.
• 5 is a cross-sectional view when the optical module is cut along a line VV, which is 3 is displayed.
• 6 is an enlarged view of a part surrounded by a dotted line A shown in 5 is displayed.
• 7 is a perspective view illustrating the substrate applied to the optical module shown in 3 is shown.
• 8th is an enlarged view of a part surrounded by a dotted line B shown in 7 is displayed.
• 9 is a schematic view of the substrate included in 7 is shown.
• 10 a top view of a part in which a depression is formed in the substrate which is in 7 is shown.
• 11 is a top view of an optical coupling module housed in the recess shown in 7 is shown.
• 12 is a plan view of the optics coupling module housed in a recess according to a second embodiment.
• 13 is a schematic view of a substrate according to the second embodiment.
• 14 Fig. 10 is a plan view of a part where the recess is formed in the substrate according to the second embodiment.
• 15 is a view illustrating a second recess according to a first modification example.
• 16 is a view showing a second recess according to a second modification example.
• 17 is a view showing a second recess according to a third modification example.

Description of embodiments

[Problem to be solved by the present disclosure]

The optical module disclosed in Patent Literature 1 has a structure in which an optical coupling module is mounted on a substrate. For this reason, the thickness of the entire optical module increases by the thickness amounts of the substrate and the optical coupling module. Thus, in order to make the optical module thinner, a recess recessed from one major surface of the substrate toward the other major surface may be formed, and at least a part of the optical coupling module may be accommodated within the recess.

However, when a recess is formed in a substrate, there is a concern that a part of a glass cloth provided inside the substrate protrudes into the recess from a side surface of the recess, which may interfere with mounting of the optical coupling module. In addition, when glass filaments protruding from the side surface of the recess are present on an optical path (for example, between a lens provided in the optical coupling module and an optical component mounted on the substrate), there is a concern that a Transmission of light is disrupted. Thus, it is desired to develop an optical module in which mountability of an optical coupling module can be improved and transmission of light can be performed more appropriately.

An object of the present disclosure is to provide an optical module and an optical connecting cable in which mountability of an optical coupling module can be improved and transmission of light can be performed appropriately.

[Effects of the present disclosure]

According to the present disclosure, it is possible to improve mountability of an optical coupling module and to perform transmission of light more appropriately.

[Description of Embodiments of the Present Disclosure]

First, details of an embodiment of the present disclosure are enumerated and described. An optical module according to one embodiment includes a substrate, an optical component and an optical coupling module. The substrate includes a glass fabric inside, which is formed from glass threads that serve as a weft thread and a warp thread. An outer edge of the substrate, viewed in a thickness direction, has a rectangular shape defined by a pair of first side surfaces in a predetermined direction and a pair of second side surfaces in a direction perpendicular to the predetermined direction. The optical component is mounted on the substrate. The optical coupling module is designed to be optically coupled to the optical component. The weft thread is inclined with respect to the first side surfaces and the second side surfaces as viewed in the thickness direction of the substrate. The warp thread is inclined with respect to the first side surfaces and the second side surfaces as viewed in the thickness direction of the substrate. A depression recessed from a first major surface of the substrate toward a second major surface of the substrate to include a bottom portion is formed in the substrate. At least a portion of the optical coupling module is housed in the recess. A side surface of the recess includes an inclined region inclined with respect to an extension direction of the weft thread and an extension direction of the warp thread, as viewed in the thickness direction of the substrate.

In this optical module, the side surface of the recess includes the inclined area. Since this inclined area is in the thickness direction of the substrate seen is inclined with respect to the extension direction of the weft thread and the extension direction of the warp thread, it is unlikely that the glass threads protrude from the inclined region into the recess. Therefore, in comparison, when the entire area of the side surface of the recess extends along the weft thread or the warp thread, the amount of glass threads protruding from the side surface of the recess into the recess can be reduced. Accordingly, interference with accommodation of the optical coupling module by the glass threads protruding into the recess is inhibited, so that mountability of the optical coupling module is improved. Furthermore, presence of the glass filaments on an optical path (for example, between a lens provided in the optical coupling module and the optical component) is inhibited and transmission of light is performed more appropriately.

As an embodiment, the recess may include a first recess and a second recess that includes a second bottom portion positioned closer to the second major surface than a first bottom portion of the first recess and includes a smaller opening area than the first recess. Both a side surface of the first recess and a side surface of the second recess may include the inclined region. The optical coupling module may include a lens that is optically coupled to the optical component. The lens can be accommodated in the second well. In this case, the entire area of the recess can be made smaller by making deep only the recess part which mainly accommodates components such as a lens, which is likely to become a component protruding from a lower surface of the optical coupling module, and other parts be made shallower than the depression part. As a result, the strength of the substrate can be maintained even by a structure in which a recess is provided in the substrate.

An optical module according to one embodiment includes a substrate, an optical component and an optical coupling module. The substrate includes a glass fabric inside, which is formed from glass threads that serve as a weft thread and a warp thread. An outer edge, viewed in a thickness direction of the substrate, has a rectangular shape defined by a pair of first side surfaces in a predetermined direction and a pair of second side surfaces in a direction perpendicular to the predetermined direction. The optical component is mounted on the substrate. The optical coupling module is designed to be optically coupled to the optical component. The weft thread extends along the first side surfaces, viewed in the thickness direction of the substrate. The warp thread extends along the second side surfaces as viewed in the thickness direction of the substrate. A depression recessed from a first major surface of the substrate toward a second major surface of the substrate to include a bottom portion is formed in the substrate. At least a portion of the optical coupling module is housed in the recess. A side surface of the recess includes an inclined region inclined with respect to an extension direction of the weft thread and an extension direction of the warp thread, as viewed in the thickness direction of the substrate.

In this optical module, the side surface of the recess includes the inclined area. Since this inclined region is inclined in the thickness direction of the substrate with respect to the extension direction of the final thread and the extension direction of the warp of the glass threads, the glass threads are unlikely to protrude from the inclined region into the recess. Therefore, in comparison with when the entire area of the side surface of the recess extends along the weft thread or the warp thread, the amount of glass threads protruding from the side surface of the recess into the recess can be reduced. Accordingly, interference with accommodation of the optical coupling module by the glass threads protruding into the recess is inhibited, so that mountability of the optical coupling module is improved. Furthermore, presence of the glass threads on an optical path is inhibited and transmission of light is carried out more appropriately.

As an embodiment, the recess may include a first recess and a second recess that includes a second bottom portion that is closer to the second adhesion surface than a first bottom portion of the first recess and includes a smaller opening area than the first recess. A side surface of the second depression may include the inclined region. The optical coupling module may include a lens that is optically coupled to the optical component. The lens can be accommodated in the second well. In this case, the entire area of the recess can be made smaller by making deep only the recess part which mainly accommodates components such as a lens, which is likely to become a component protruding from a lower surface of the optical coupling module, and other parts be made shallower than the depression part. As a result, the strength of the substrate itself can be maintained by a structure in which a recess is provided in the substrate.

As an embodiment, the inclined region may be a curved surface that is curved as viewed in the thickness direction of the substrate. An outer edge of the recess viewed in the thickness direction of the substrate may have an oval shape or a fan shape defined by the side surface of the recess. In this case, the recess having the side surface including the inclined region can be easily formed by a simple structure.

As an embodiment, an outer edge of the recess, viewed in the thickness direction of the substrate, may have a diamond shape or a triangular shape defined by the side surface of the recess. In this case, the recess having the side surface including the inclined region can be easily formed by a simple structure.

As an embodiment, an angle formed by the inclined region and the extension direction of the weft thread, viewed in the thickness direction of the substrate, may be equal to or greater than 10° and equal to or less than 80°. An angle formed by the inclined region and the extension direction of the warp thread, viewed in the thickness direction of the substrate, may be equal to or greater than 10° and equal to or less than 80°. In this case, the glass threads can be more reliably prevented from protruding from the inclined area into the recess. For this reason, mountability of the optical coupling module is further improved and transmission of light is performed more appropriately.

As an embodiment, the optical coupling module may include a holding portion for holding end portions of optical fibers optically coupled to the optical component via the optical coupling module. In this case, since the end portions of the optical fibers are appropriately held by the holding portion of the optical coupling module, optical coupling between the optical component and the optical fibers can be performed more precisely.

As an embodiment, a penetration hole penetrating the bottom portion of the second main surface may be formed in the recess. The optical component may be mounted on the second major surface so that it overlaps the penetration hole as viewed from above the second major surface. In this case, the optical coupling module and the optical component mounted on the second main surface of the substrate can be optically coupled by a simple structure such as a penetrating hole.

An optical connection cable according to an embodiment includes any of the optical modules described above and at least one optical fiber cable. The optical fiber cable includes an optical fiber. The optical fiber cable is attached to the optical module so that the optical fiber is optically coupled to the optical component via the optical coupling module. In this optical connecting cable, like the optical module described above, mountability of the optical coupling module can be improved and transmission of light can be performed appropriately.

[Details of Embodiments of the Present Disclosure]

Concrete examples of an optical module and an optical connection cable according to the present disclosure will be described below with reference to the drawings. The present disclosure is not limited to these examples and is indicated by the claims; and all changes are intended to be included within the meaning and a range of equivalence of the claims. The same reference numerals will be applied to the same elements in the description of the drawings and their repeated description will be avoided.

<First Embodiment>

With reference to 1 and 2 an optical connection cable 1 according to an embodiment is described. 1 is a perspective view showing an end portion of the optical connecting cable 1 according to the embodiment. 2 is a perspective view showing the end portion of the optical connecting cable 1 from which a protection member 20 is removed. Hereinafter, for the purpose of description, a width direction of the end portion of the optical connecting cable 1 is considered as an X direction, an extension direction of the end portion is considered as a Y direction, and a thickness direction of the end portion is considered as a Z direction. In the present embodiment, the X direction, the Y direction and the Z direction are perpendicular to each other.

The optical connection cable 1 is, for example, a cable used for transmitting and receiving optical signals between devices. As in 1 and 2 shown, the optical connection cable 1 includes an optical fiber cable 10, the protective element 20 and an optical module 30. At 1 and 2 one end of the optical fiber cable 10 is shown. The other end of the optical fiber cable 10 can also have a similar configuration.

As in 2 As shown, the optical fiber cable 10 has a plurality of optical fibers and a cable jacket 12. Each of the optical fibers 11 is an element for transmitting optical signals. A large portion of each of the optical fibers 11 is housed within the cable jacket 12. A tip part of each of the optical fibers 11 is exposed to the outside of the cable jacket 12. The plurality of optical fibers 11 are arranged in the X direction in a one-dimensional manner. Within the cable jacket 12, all optical fibers 11 are housed close to one another in a bundle. On the other hand, outside the cable jacket 12, the plurality of optical fibers branch into several (4 to 6 in the present embodiment) bundles, and an end portion of each of the bundles is held by an optical coupling module 50. For example, each of the optical fibers 11 has a glass fiber and a resin coating. For example, the fiberglass includes a core and a cladding surrounding the core. Each of the optical fibers 11 may be a single-mode optical fiber (SMF) or a multi-mode optical fiber (MMF).

As in 1 As shown, the protective member 20 is a member having a flat shape extending in the X direction and the Y direction. The optical module 30 is housed within the protective element 20. The protective element 20 protects the optical module 30 from external influences or the like. The protective member 20 has a laminated structure formed of an inner layer 21 and an outer layer 22 covering the inner layer 21. For example, the inner layer 21 is made of a metal. For example, the outer layer 22 is formed of a resin.

At the tip of the optical connecting cable 1, part of the inner layer 21 is exposed from the outer layer 22. For example, the exposed part of the inner layer 21 is inserted into a socket provided in a device to which the optical connecting cable 1 is connected.

Next, the optical module 30 will be described with reference to 3 to 6 described. 3 is a top view of the optical module 30 seen from above a first main surface 41 of a substrate 40. 4 is a top view of the optical module 30 seen from above a second main surface 42 of the substrate 40. 5 is a cross-sectional view when the optical module 30 is cut along a line VV shown in 3 is displayed. 6 is an enlarged view of a part surrounded by a dotted line A shown in 5 is displayed. The optical module 30 includes the substrate 40, a plurality of optical coupling modules 50, a plurality of optical components 60 and a plurality of integrated circuits (IC) 61.

The substrate 40 is a plate-shaped member on which various types of optical components and electronic components are mounted. The substrate 40 is a multilayer substrate formed of a plurality of laminated resin layers or a single-layer substrate formed of a resin layer. For example, the resin layer is formed of an epoxy resin, a polyimide resin, or a fluorine resin. In the present embodiment, a thickness direction of the substrate 40 coincides with the Z direction. The substrate 40 has a pair of side surfaces 40a and 40b (first side surface) and a pair of side surfaces 40c and 40d. Viewed in the Z direction, the side surfaces 40a and 40b extend in the X direction (predetermined direction). Viewed in the Z direction, the side surfaces 40c and 40d extend in the Y direction (direction perpendicular to the predetermined direction). As viewed in the Z direction, an outer edge of the substrate 40 has a rectangular shape defined by the pair of side surfaces 40a and 40b and the pair of side surfaces 40c and 40d. That is, the substrate 40 is a rectangular substrate. The substrate 40 has the first main surface 41 and the second main surface 42 facing each other in the Z direction. The thickness of the substrate 40 may be equal to or greater than 0.2 mm and equal to or less than 0.8 mm.

The substrate 40 has at least a piece of a glass fabric 70 inside. The glass fabric 70 is a woven fabric formed from glass threads that serve as weft threads and warp threads. In 3 and 4 For a convenient description, only part of the glass fabric 70 is shown. However, in the present embodiment, the glass cloth 70 is provided in the entire area of the substrate 40 as viewed in the Z direction. That is, viewed in the Z direction, an outer edge of the glass fabric 70 coincides with the outer edge of the substrate 40. When the substrate 40 is a multilayer substrate, the glass cloth 70 may be provided in each of the plurality of resin layers that form the substrate 40. In the present embodiment, the substrate 40 is a multilayer substrate, and a plurality of pieces of glass cloth 70 are laminated in the Z direction. A detailed nature of the glass fabric 70 will be described below.

Various types of wirings (not shown) for electrically connecting the integrated circuits 61 and other electronic components are provided on an inward side of the substrate 40. In the following description, an end portion where the side surface 40a is positioned in the Y direction can be regarded as a tip of the optical module 30, and an end portion where the side surface 40b can be viewed as a base end of the optical module 30. In addition, a surface where the first main surface 41 is positioned in the Z direction may be regarded as an upper surface of the optical module 30, and a surface where the second main surface 42 is positioned may be regarded as a lower surface of the optical module 30 .

As in 3 As shown, the first main surface 41 is a surface extending in the X direction and the Y direction, and has a rectangular shape in a plan view. A plurality of grids 41a, which are metal films, are provided in an area near the side surface 40a on the first main surface 41. For example, each of the grids 41a may be connected to the integrated circuits 61 via the wirings or the like within the substrate 40. On the other hand, the plurality of optical coupling modules 50 are placed side by side in the X direction in an area near the side surface 40b on the first main surface 41.

As in 4 As shown, the second main surface 42 is a surface extending in the X direction and the Y direction, and has a rectangular shape in a plan view. The plurality of optical components 60 and the plurality of integrated circuits 61 are mounted on the second main surface 42 in an area near the side surface 40b. In 4 Each of the optical components 60 is indicated by a dotted line for convenient description. For example, each of the optical components 60 is a light-receiving component such as a photodiode (PD). A light-receiving surface of each of the optical components 60 faces the optical coupling module 50. Each of the optical components 60 overlaps a penetration hole 48a provided in the substrate 40 as viewed from above the second main surface 42 (in the Z direction). Accordingly, the optical component 60 can receive light from the optical coupling module 50 facing it with the substrate 40 sandwiched therebetween through the penetration hole 48a. In order to arrange the optical component 60 on the second main surface 42, the opening area of the penetration hole 48a on the second main surface 42 is smaller than the surface area of the surface which faces the second main surface 42 in the optical component 60. Each of the integrated circuits 61 is an integrated circuit for controlling an operation of the optical component 60. For example, each of the integrated circuits 61 may be connected to the optical component 60 via a wiring within the substrate 40, a bonding wire, or the like. In the present embodiment, an integrated circuit 61 is connected to three optical components 60. A high communication speed between the integrated circuit 61 and the optical component 60 can be maintained by arranging the integrated circuit 61 close to (for example, arranging the integrated circuit 61 adjacent to) the optical component 60.

The optical coupling module 50 is a component for optically coupling the optical fibers 11 and the optical components 60. The optical coupling module 50 is formed of a material that allows light emitted from the optical fibers 11 to be transmitted therethrough (for example, a glass or a light-transmitting resin) . As in 3 As shown, the optical coupling module 50 has a substantially rectangular shape as viewed in the Z direction. The optical coupling module 50 has a tip surface 50a and a pair of side surfaces 50b. The tip surface 50a is a surface extending in the X direction and the Z direction and connects the pair of side surfaces 50b. Each of the side surfaces 50b is a surface extending in the Y direction and the Z direction.

Additionally, as in 5 As shown, the optical coupling module 50 has a groove portion 51, an upper surface 52, a lower surface 53, a bearing surface 54, a mirror 55, and a lens 56. The groove portion 51 is a V-groove extending in the Y direction (a Groove having a V-shape in an The end portions of the optical fibers 11 placed in the groove portion 51 are fixed to the groove portion 51 using, for example, an adhesive. The adhesive may be, for example, a UV-curing adhesive or may be a light-transmitting adhesive that allows light L emitted from the optical fibers 11 to be transmitted therethrough. The shape of the groove portion 51 is not limited to the V-groove. For example, the shape of the groove portion 51 may be a U-groove having a rounded bottom portion, or may be a rectangular groove having a bottom surface extending in the X direction and the Y direction. The holding portion (in the present embodiment, the groove portion 51) for holding the end portions of the optical fibers 11 need not necessarily be provided in the optical coupling module 50. For example, the groove portion 51 may be provided on another component that is different from the optical coupling module 50. For example, when the groove portion 51 is provided on another component, the optical coupling module 50 may have a pair of protruding portions, and another component provided with the groove portion 51 may have a pair of recessed portions. The optical coupling module 50 and another component may be connected by fitting each of the protruding portions of the optical coupling module 50 into a respective one of the recessed portions of another component.

The upper surface 52 is a surface positioned in an upper portion of the optical coupling module 50 and extends in the X direction and the Y direction. The upper surface 52 is positioned closer to the tip surface 50a of the optical coupling module 50 with respect to the groove portion 51. The upper surface 52 is provided with a trough, the surface of which acts as the mirror 55. The lower surface 53 is a surface positioned in a lower portion of the optical coupling module 50 and extends in the X direction and the Y direction.

The abutment surface 54 is a surface with which tip surfaces of the optical fibers 11 abut and extends in the X direction and the Z direction. The abutment surface 54 connects the end portion of the groove portion 51 and the end portion of the upper surface 52 in the Y direction Light L, which is emitted by the optical fibers 11, passes through the contact surface 54 and strikes the mirror 55. The contact surface 54 and the tip surfaces of the optical fibers 11 do not have to come into direct contact with one another. For example, a light transmitting adhesive that allows the light L to be transmitted therethrough or a refractive index adjusting agent may be inserted between the abutment surface 54 and the tip surfaces of the optical fibers 11.

The mirror 55 is an element that converts a continuation direction of the light L emitted from the optical fibers 11. The mirror 55 is provided in such a way that it is inclined with respect to both an XY plane and an XZ plane. The mirror 55 receives the light L emitted from the optical fibers 11 in the Y direction and reflects the light L in the Z direction toward the lens 56. An incident optical axis and a reflection optical axis of the light L may form a right angle, for example. The light L reflected by the mirror 55 is incident on the optical component 60 through the lens 56 and the penetrating hole 48a.

The lens 56 is an element that is optically coupled to the optical component 60. The lens 56 is provided in the optical coupling module 50 in a part that protrudes toward the second main surface 42 in the Z direction. As in 6 As shown, the lens 56 faces the optical component 60 in the Z direction and has a surface that is curved in a projection shape toward the optical component 60. A focus F of the lens 56 is positioned within the optical component 60 with respect to the surface of the optical component 60. The lens 56 focuses the light L reflected by the mirror 55 and causes it to impinge on the optical component 60. Various types of parameters of the lens 56 (e.g., the surface shape, the size, the material, and the like of the lens 56) are optimized so that the focus F of the lens 56 is positioned within the optical component 60.

Next will be with reference to 7 and 8th a precise nature of the substrate 40 is described. 7 is a perspective view showing the substrate 40. 8th is an enlarged view of a part surrounded by a dotted line B shown in 7 is displayed. In 7 and 8th A representation of the optical coupling modules 50 is omitted for a useful description. As in 7 shown, a plurality of depressions 43 are formed in the substrate 40. Each of the depressions 43 is a trough that is recessed from the first main surface 41 toward the second main surface 42. The optical coupling module 50 is housed within a respective one of the recesses 43. The plurality of depressions 43 are provided side by side in the X direction. The number of depressions 43 may be equal to or greater than the number of optical coupling modules 50 mounted in the substrate 40. In the present embodiment, the same number (four) of recesses 43 as the number of optical coupling modules 50 are formed. For example, each of the recesses 43 may be formed by cylinder countersinking. A beam portion 43a extending from the inside to the outside of the substrate 40 in the Y direction is provided between the recesses 43 adjacent to each other. The beam portion 43a has a shape rising from a first bottom portion 45 of each of the depressions 43 toward the first main surface 41 of the substrate 40.

Each of the wells 43 includes a first well 44 and a second well 47. The first well 44 is a trough that forms the majority of the well 43 and has the first bottom portion 45 and side surfaces 46. The first bottom portion 45 is a part in which the optical coupling module 50 is placed. In the present embodiment, it is a surface extending in the X direction and the Y direction. Viewed in the Z direction, an outer edge of the first bottom portion 45 has a rectangular shape having long sides in the Y direction. The first bottom portion 45 has a size that allows the optical coupling module 50 to be placed in its entirety. The optical coupling module 50 placed on the first bottom portion 45 includes not only a case where the optical coupling module 50 is placed so as to be in direct contact with the first bottom portion 45 but also a case where the optical coupling module 50 is placed on the first bottom portion 45 by means of a member such as an adhesive.

As in 8th As shown, the first bottom portion 45 has a pair of positioning holes 45a. Each of the positioning holes 45a is a hole penetrating the first bottom portion 45 to the second main surface 42 (see Fig 4 ). The pair of positioning holes 45a functions as a positioning mechanism for the optical coupling module 50 with respect to the recess 43. For example, the pair of projection portions corresponding to the pair of positioning holes 45a are provided in the optical coupling module 50 and the lens 56 (see Fig 5 ) and the optical component 60 can be suitably optically coupled by placing the optical coupling module 15 so that each of the pair of projection portions is fitted into a respective one of the pair of positioning holes 45a. The number of positioning holes 45a may be one. However, positioning of the optical coupling module 50 can be performed more precisely by forming two or more positioning holes 45a. Each of the positioning holes 45a need not penetrate from the first bottom portion 45 to the second main surface 42, and may be a non-penetration hole having a bottom surface.

A design of the positioning mechanism used to position the optical coupling module 50 is not limited to the positioning holes 45a. For example, the lens 56 of the optical coupling module 50 and the optical component 60 can be suitably optically coupled by providing a mark on both the first bottom portion 45 and the optical coupling module 50 and placing the optical coupling module 50 at a position where the marks overlap each other. In order for the mark provided in the first bottom portion 45 to be visually recognized by the optical coupling module 50, the material of the optical coupling module 50 may be a material that allows visible light to be transmitted therethrough (for example, a glass or a light-transmitting resin).

The side surfaces 46 are surfaces that connect the first bottom section 45 and the first main surface 41 to one another. The side surfaces 46 are surfaces that rise from the outer edge of the first bottom section 45 towards the first main surface 41 of the substrate 40. The side surfaces 46 define an outer edge of the first recess 44, viewed in the Z direction. The side surfaces 46 may be parallel to the Z direction and may be inclined. The side surfaces 46 include a side surface 46a and a pair of side surfaces 46b. As in 7 As shown, the side surface 46a is a surface positioned at the end portion near the side surface 40a at the first recess 44 and connects the pair of side surfaces 46b together. The side surface 46a extends in the X direction as viewed in the Z direction. A corner portion where the side surface 46a and the first bottom portion 45 intersect may have an R shape.

The pair of side surfaces 46b are surfaces facing each other in the X direction. Each of the side surfaces 46b extends in the Y direction as viewed in the Z direction. A corner portion where each of the side surfaces 46b and the first bottom portion 45 intersect may have an R shape. In addition, no side surface is provided at the end portion near the side surface 40b at the first recess 44. That is, the recess 43 opens on the side surface 40b. Accordingly, the optical coupling module 50 can be accommodated through the opening within the recess 43. In addition, in a state where the optical coupling module 50 is accommodated in the recess 43, the optical fibers 11 connected to the optical coupling module 50 can be pulled out through the opening to the outward side of the recess 43.

As in 8th shown, the second depression 47 is a trough which is provided in the first bottom section 45 of the first depression 44. The second depression 47 is designed to extend in the X direction. The second recess 47 has a smaller opening area than the first recess 44. The opening area of the second recess 47 is an opening area in the first bottom portion 45 and the opening area of the first recess 44 is an opening area in the first main surface 41. The second recess 47 has a second bottom portion 48 and side surfaces 49. The second bottom portion 48 is positioned closer to the second main surface 42 than the first bottom portion 45. In the present embodiment, the second bottom portion 48 is a surface extending in the X direction and the Y direction. Viewed in the Z direction, an outer edge of the second bottom portion 48 has a rectangular shape having long sides in the X direction. A part of the optical coupling module 50 (a part on which the lens 56 is formed) is placed at the second bottom portion 48 (see 5 ). The lens 56 is housed in the second recess 47.

A plurality of penetration holes 48a are formed in the second bottom portion 48. In the present embodiment, two round holes and one long hole are formed as the penetrating holes 48a for every second recess 47. The The number and shape of the penetration holes 48a are not limited and may be appropriately changed in accordance with the number or shape of the optical components 60 mounted on the second main surface 42. As in 6 As shown, the penetration hole 48a penetrates the second bottom portion 48 to the second main surface 42. The light L from the lens 56 towards the optical component 60 passes through the inside of the penetration hole 48a. The penetration hole 48a has a cone shape in which the inner diameter decreases from the second bottom portion 48 toward the second main surface 42. The inner diameter and the cone angle of the penetration hole 48a are optimized to a size that does not disturb the course of the light L. The penetration hole 48a may be a straight penetration hole having a constant inner diameter size.

The side surfaces 49 are surfaces that connect the second floor section 48 and the first floor section 45 to one another. The side surfaces 49 are surfaces that rise from the outer edge of the second floor section 48 towards the first floor section 45. The side surfaces 49 define an outer edge of the second recess 47, viewed in the Z direction. The side surfaces 49 can be parallel to the Z direction or can be inclined. The side surfaces 49 include a pair of side surfaces 49a and a pair of side surfaces 49b. The pair of side surfaces 49a are surfaces facing each other in the Y direction. Each of the side surfaces 49a connects the pair of side surfaces 49b. Each of the side surfaces 49a extends in the X direction as viewed in the Z direction. Corner portions where each of the side surfaces 49a and the second bottom portion 48 intersect may have an R shape. The pair of side surfaces 49b are surfaces facing each other in the X direction. Each of the side surfaces 49b extends in the Y direction as viewed in the Z direction. Corner portions where each of the side surfaces 49b and the second bottom portion 48 intersect may have an R shape.

With reference to 9 Details of the glass fabric 70 are described. 9 is a schematic view of the substrate 40. 9 represents the substrate 40 before the plurality of depressions 43 are formed. In 9 A representation of various types of structures such as the optical components 60 and the integrated circuits 61 provided in the substrate 40 is omitted.

As in 9 shown, the glass fabric 70 is provided within the substrate 40. The glass fabric 70 is a woven fabric formed from glass threads 71 serving as weft thread 72 and warp thread 73. The glass cloth 70 has a plate shape that has meshes. In the glass fabric 70, the weft thread 72 and the warp thread 73 intersect each other regularly. For example, the weaving density of the weft thread 72 and the weaving density of the warp thread 73 are equal to or more than 50 threads/25 mm and equal to or less than 100 threads/25 mm. The glass threads 71, which form the weft thread 72 and the warp thread 73, are formed, for example, from bundles of approximately several 100 (for example, equal to or more than 100 and equal to or less than 500) glass filaments. The diameter of each of the glass filaments is, for example, approximately several micrometers (e.g., equal to or greater than 1 μm and equal to or less than 10 μm). In 9 For a convenient description, the intervals between threads of the weft thread 72 and between threads of the warp thread 73 are shown larger than the actual intervals.

The weft thread 72 is inclined in the Z direction with respect to the X direction and the Y direction. That is, the weft thread 72 is inclined with respect to the side surfaces 40a and 40b and the side surfaces 40c and 40d as viewed in the Z direction. Viewed in the Z direction, an angle formed by the extending direction of the weft thread 72 and the side surfaces 40a and 40b (an angle which is an acute angle) may be, for example, equal to or greater than 10° and equal to or less than 80° ° or may be equal to or greater than 40° and equal to or less than 50°. In the present embodiment, the angle formed by the extending direction of the weft thread 72 and the side surfaces 40a and 40b is 45°. Also, viewed in the Z direction, an angle formed by the extending direction of the weft thread and the side surfaces 40c and 40d (an angle that is an acute angle) may be, for example, equal to or greater than 10° and equal to or less than 80° or may be equal to or greater than 40° and equal to or less than 50°. In the present embodiment, the angle formed by the extending direction of the weft thread and the side surfaces 40a and 40b is 45°.

The warp thread 73 is inclined with respect to the X direction and the Y direction as viewed in the Z direction. That is, the warp thread 73 is inclined with respect to the side surfaces 40a and 40b and the side surfaces 40c and 40d as viewed in the Z direction. Viewed in the Z direction, an angle formed by the extending direction of the warp thread 73 and the side surfaces 40a and 40b (an angle that is an acute angle) may be, for example, equal to or greater than 10° and equal to or less than 80° or may be equal to or greater than 40° and equal to or less than 50°. In the present embodiment, the angle through the direction of extension of the warp thread 73 and the side surfaces 40a and 40b is 45°. Also, viewed in the Z direction, an angle formed by the extension direction of the warp thread 73 and the side surfaces 40c and 40d (an angle that is an acute angle) may be, for example, equal to or greater than 10° and equal to or less than 80° or may be equal to or greater than 40° and equal to or less than 50°. In the present embodiment, the angle formed by the extending direction of the warp thread 73 and the side surfaces 40c and 40d is 45°.

The recesses 43 are formed, for example, by cylindrical depressions in the substrate 40 in which the glass fabric 70 is arranged. With reference to 10 a relationship between the recesses 43 and the glass fabric 70 is described. 10 is a plan view of a part where the recess 43 is formed in the substrate 40. In 10 For a convenient description, the intervals between threads of the weft thread 72 and between threads of the warp thread 73 are shown larger than the actual intervals. In addition, in 10 omitted from the illustration of a part of the glass fabric 70 provided inside the substrate 40 and overlapping the recess 43. However, the glass fabric 70 is actually also provided between the first bottom portion 45 and the second bottom portion 48 and the second main surface 42 (see 5 ).

As described above, the first recess 44 has the side surface 46a and the pair of side surfaces 46b. The side surface 46a extends in the X direction as viewed in the Z direction. For this reason, the side surface 46a is inclined with respect to the extending direction of the weft thread 72 and the extending direction of the warp thread 73 as viewed in the Z direction. The side surfaces 46b extend in the Y direction as viewed in the Z direction. For this reason, the side surfaces 46b are inclined with respect to the extending direction of the weft thread 72 and the extending direction of the warp thread 73 as viewed in the Z direction.

The side surfaces 46 include inclined areas S1, which are inclined in the direction Z with respect to the direction of extension of the weft thread 72 and the direction of extension of the warp thread 73. In the present embodiment, the entire areas of the side surface 46a and the side surfaces 46b form the inclined regions S1. As viewed in the Z direction, an angle formed by the inclined regions S1 and the extension direction of the weft thread 72 (an angle which is an acute angle) may be, for example, equal to or greater than 10° and equal to or less than 80° °, as an example it is 45° in the present embodiment. In addition, an angle formed by the inclined regions S1 and the extending direction of the warp thread 73 (an angle that is an acute angle) viewed in the direction Z may be, for example, equal to or greater than 10° and equal to or less than be 80°, or may be equal to or greater than 40° and equal to or less than 50°. In the present embodiment, the angle formed by the inclined regions S1 and the extending direction of the warp thread 73 is 45°.

The second recess 47 has the pair of side surfaces 49a and the pair of side surfaces 49b. The side surfaces 49a extend in the X direction as viewed in the Z direction. For this reason, the side surfaces 49a are inclined with respect to the extending direction of the weft thread 72 and the extending direction of the warp thread 73 as viewed in the Z direction. The side surfaces 49b extend in the Y direction as viewed in the Z direction. For this reason, the side surfaces 49b are inclined with respect to the extending direction of the weft thread 72 and the extending direction of the warp thread 73 as viewed in the Z direction.

The side surfaces 49 include inclined areas S2, which are inclined with respect to the extension direction of the final thread 72 and the extension direction of the warp thread 73, viewed in the Z direction. In the present embodiment, the entire areas of the side surfaces 49a and the side surfaces 49b form the inclined regions S2. As viewed in the Z direction, an angle formed by the inclined regions S2 and the extension direction of the weft thread (an angle which is an acute angle) may be, for example, equal to or greater than 10° and equal to or less than 80° be, it is 45° in the present embodiment as an example. In addition, an angle formed by the inclined regions S2 and the extending direction of the warp thread 73 (an angle that is an acute angle) viewed in the direction Z may be, for example, equal to or greater than 10° and equal to or less than 80° or may be equal to or greater than 40° and equal to or less than 50°. In the present embodiment, the angle formed by the inclined regions S2 and the extending direction of the warp thread 73 is 45°.

With reference to 5 and 11 A way of accommodating the optical coupling module 50 in the recess 43 will be described. 11 is a top view of the optical coupling module 50 housed in the recess 43. In 11 are like 10 the intervals between threads of the weft thread 72 and between threads of the warp thread 73 are shown larger than the actual ones Intervals and an illustration of a portion of the glass fabric 70 provided within the substrate 40 and overlapping the first bottom portion 45 and the second bottom portion 48 are omitted.

As in 5 As shown, a major part of the optical coupling module 50 is housed in the first recess 44, and a part to which the lens 56 is provided (a part protruding to the lower side in the Z direction) is housed in the second recess 47. Portions of the optical fibers 11 positioned on the substrate 40 (attachments) extend along the first main surface 41 of the substrate 40. Center axes of the attachment portions are positioned within the recess 43. The end portions of the optical fibers 11 extend straight without causing bending on the side surface 40b of the substrate 40.

A depth D1 of the first recess 44 is optimized in accordance with a thickness T of the optical coupling module 50, for example. Here, the depth D1 is a distance from the first main surface 41 to the first bottom portion 45 in the thickness direction (Z direction) of the substrate 40. The thickness T is a distance from the upper surface 52 to the lower surface 53 in the Z direction Depth D1 may be a size equivalent to at least half the thickness T of the optical coupling module 50. In addition, in the present embodiment, the depth D1 is the size equivalent to at least one half of the thickness of the substrate 40 (a distance from the first main surface 41 to the second main surface 42). For example, when the thickness of the substrate 40 is 10, the depth D1 may be equal to or greater than 6 and equal to or less than 8. As the depth D1 increases, more parts of the optical coupling module 50 are accommodated in the recess 43 and therefore the optical module 30 becomes thinner. In the present embodiment, the top surface 52 is positioned outside the recess 43 (one side above the first main surface 41). However, the depth D1 may be greater so that the top surface 52 is positioned within the recess 43 (at the same height as the first main surface 41 or on a side below the first main surface 41).

A depth D2 of the second recess 47 is greater than the depth D1. Here, the depth D2 is a distance from the first main surface 41 to the second bottom portion 48 in the thickness direction of the substrate 40. For example, when the thickness of the substrate 40 is 10, the depth D2 may be equal to or larger than 7 and equal to or smaller be as 9. For example, the depth D2 may be optimized in accordance with the thickness T of the optical coupling module 50.

As in 11 shown, in the present embodiment the optical coupling module 50 is arranged in its entirety on the substrate 40. The optical coupling module 50 in its entirety need not be disposed on the substrate 40, and a part of the optical coupling module may be disposed on the outward side of the substrate 40 (a position that does not overlap the substrate 40 in the Z direction). For example, the end part of the optical coupling module 50 (a lower part in 10 ) may be arranged on the external side of the substrate 40.

The optical coupling module 50 is housed in the recess 43, so that gaps 80 are provided between the side surfaces 46 and the optical coupling module 50. Specifically, a gap 81 is provided between the tip surface 50a and the side surface 46a, and gaps 82 are provided between the respective side surfaces 50b and the respective side surfaces 46b. For example, a width W1 of the gap 81 in the Y direction may be equal to or larger than 50 μm and equal to or smaller than 500 μm. Widths W2 of the column 82 in the direction The widths W2 can be larger than the width W1.

The optical coupling module 50 is fixed to the substrate 40 using an adhesive 85. As in 5 shown, the adhesive 85 is arranged between the lower surface 53 and the first bottom section 45. In order to prevent the optical path of the light L from being disturbed by the adhesive 85, it is possible that the adhesive 85 is not disposed within the second recess 47. Additionally, as in 11 shown, the adhesive 85 is also arranged in the gap 81. The adhesive 85 is applied to the first bottom portion 45 and the optical coupling module 50 is placed on the applied adhesive 85. Accordingly, the adhesive 85 is distributed, for example due to the empty weight of the optical coupling module 50, and flows into the gaps 81 and 82. For example, the adhesive 85 is a UV-curable adhesive or a light-transmitting adhesive. The amount of adhesive 85 applied per optical coupling module 50 is, for example, equal to or greater than 1 mg and equal to or less than 10 mg.

As for the optical module 30 and the optical connecting cable 1 according to the present embodiment, the side surfaces 46 and 49 of the recess 43 include the inclined regions S1 and S2. Since the inclined regions S1 and S2 are inclined in the direction Z with respect to the extending direction of the weft thread 72 and the extending direction of the warp thread 73, it is untrue It appears that the glass threads 71 protrude from the inclined areas S1 and S2 into the recess 43. Therefore, in comparison, when the entire portions of the side surfaces 46 and 49 of the recess 43 extend along the weft 72 or the warp 73, the amount of glass threads 71 protruding from the side surfaces 46 and 49 of the recess 43 into the recess 43 can be reduced , be reduced. Accordingly, interference with accommodation of the optical coupling module 50 by the glass threads 71 protruding into the recess 43 is inhibited, so that mountability of the optical coupling module 50 is improved. Furthermore, presence of the glass threads 71 on the optical path (for example, between the lens 56 and the optical component 60) is inhibited and transmission of the light L is performed more appropriately.

In the above embodiment, as viewed in the Z direction, an angle formed by the inclined regions S1 and S2 and the extending direction of the weft thread 72 may be equal to or greater than 10° and equal to or less than 80°. As viewed in the Z direction, an angle formed by the inclined regions S1 and S2 and the extension direction of the warp thread 73 may be equal to or greater than 10° and equal to or less than 80°. In this case, the glass threads 71 can be more reliably prevented from protruding into the recess 43 from the side surfaces 46 and 49 of the recess 43. For this reason, mountability of the optical coupling module 50 is further improved and transmission of the light L is performed more appropriately.

In the above embodiment, the optical coupling modules 50 each have groove portions 51 (holding portions) for holding the end portions of the optical fibers 11 optically coupled to the optical components 60 via the optical coupling modules 50. In this case, since the end portions of the optical fibers 11 are adequately held by the groove portions 51 of the optical coupling modules 50, optical coupling between the optical components 60 and the optical fibers 11 can be performed more adequately.

In the above embodiment, the penetration holes 48a penetrating the second bottom portion 48 to the second main surface 42 are formed in the recesses 43. The optical components 60 are mounted on the second main surface 42 so that they overlap the penetration holes 48a as viewed from above the second main surface 42 (in the Z direction). In this case, the optical coupling modules 50 and the optical components 60 mounted on the second main surface 42 of the substrate 40 can be optically coupled by a simple structure such as the penetration holes 48a.

In the above embodiment, the recesses 43 have the first recesses 44 close to the first main surface 41 and the second recesses 47 having the second bottom portion 48 positioned closer to the second main surface 42 than the first bottom portions 45 of the first recesses 44. In In this case, the entire areas of the recesses 43 can be made smaller by only accommodating the recess parts (parts of the second recesses 47) which mainly accommodate components such as the lenses 56, which are likely to become components from the lower surfaces 53 of the optical coupling modules 50 protrude, are made deep and other parts (parts of the first recesses 44) are made shallower than the recess parts. As a result, the strength of the substrate 40 can be maintained even in a condition in which the depressions 43 are provided in the substrate 40.

<Second Embodiment>

An optical module 130 according to a second embodiment is described with reference to 12 to 14 described. 12 is a top view of the optical coupling module 50 housed in a recess 143 according to the second embodiment. 13 is a schematic view of a substrate 140 according to the second embodiment. 13 represents the substrate 140 before a plurality of depressions 143 are formed. 14 is a plan view of a part where the recess 143 is formed in the substrate 140 according to the second embodiment. In the following description, aspects different from the optical module 30 according to the first embodiment will be mainly described, and description of the same aspects will be omitted.

In the second embodiment, the direction of a glass cloth 170 provided in the substrate 140 and the nature of a second recess 147 are different from those in the first embodiment. The nature of the second embodiment is otherwise the same as that of the first embodiment. As in 13 As shown, the substrate 140 has a pair of side surfaces 140a and 140b and a pair of side surfaces 140c and 140d. Viewed in the Z direction, each of the side surfaces 140a and 140b extends in the X direction (predetermined direction). Viewed in the Z direction, each of the side surfaces 140c and 140d extends in the Y direction (a direction perpendicular to the predetermined direction). As viewed in the Z direction, an outer edge of the substrate 140 has a rectangular shape defined by the side surfaces 140a and 140b and the side surfaces 140c and 140d. The glass web 170 is provided within the substrate 140.

The glass fabric 170 has a weft thread 172 and a warp thread 173. The weft thread 172 extends in the direction right angle. The warp thread 173 extends in the Y direction. That is, when viewed in the Z direction, the warp thread 173 extends along the side surfaces 140c and 140d and intersects the side surfaces 140a and 140b at a right angle.

As in 14 shown, the depressions 143 in the substrate 140 are formed, for example, by cylinder depressions. Like the recess 43 according to the first embodiment, the plurality of recesses 143 are formed in the substrate 140. The optical coupling module 50 is housed in a respective one of the plurality of recesses 143. The depression 143 has a first depression 144 and the second depression 147. The nature of the first depression 144 is the same as the nature of the first depression 44. The first depression 144 has a first bottom section 145 and side surfaces 146. The first bottom section 145 is a surface , where the optical coupling module 50 is placed, and extends in the X direction and the Y direction in the present embodiment. The side surfaces 146 include a side surface 146a and a pair of side surfaces 146b. The side surface 146a extends in the X direction as viewed in the Z direction. The side surfaces 146b extend in the Y direction as viewed in the Z direction.

The second recess 147 has a second bottom portion 148 and side surfaces 149. As in the first embodiment, a part of the optical coupling module 50 (a part on which the lens 56 is formed, which is in 5 is shown) placed at the second floor section 148. The second bottom portion 148 extends in the X direction and the Y direction. Viewed in the Z direction, an outer edge of the second bottom portion 148 has a diamond shape. One axis of symmetry of the diamond shape extends in the X direction and the other axis of symmetry extends in the Y direction.

The side surfaces 149 are surfaces that connect the second floor section 148 and the first floor section 145 to one another. The side surfaces 149 are surfaces that rise from the outer edge of the second floor section 148 towards the first floor section 145. The side surfaces 149 may be parallel to the Z direction or may be inclined. The side surfaces 149 include the side surfaces 149a, 149b, 149c and 149d. As viewed in the Z direction, each of the side surfaces 149a, 149b, 149c and 149d extends along the side of the diamond shape shown by the outer edge of the second bottom portion 48. Accordingly, viewed in the Z direction, an outer edge of the second recess 147 has a diamond shape which is defined by the side surfaces 149. Viewed in the Z direction, each of the side surfaces 149a, 149b, 149c and 149d is inclined with respect to the X direction and the Y direction.

The side surfaces 149 of the second recess 147 include the inclined regions S2 inclined with respect to the extending direction of the weft thread (X direction) and the extending direction of the warp thread 172 (Y direction) as viewed in the Z direction. In the present embodiment, the entire areas of each of the side surfaces 149a, 149b, 149c, and 149d constitute the inclined regions S2. As viewed in the Z direction, an angle formed by the inclined regions S2 and the extending direction of the weft thread 172 may be, for example, equal to or greater than 10° and equal to or smaller than 80°, or may be equal to or greater than 40° and equal to or smaller than 50°. In addition, as viewed in the direction Z, an angle formed by the inclined regions S2 and the extending direction of the warp thread 173 may be, for example, equal to or greater than 10° and equal to or smaller than 80°, or may be equal to or greater than 40° and equal to or smaller than 50°.

Above, in the optical module 130 according to the present embodiment, the side surfaces 149 of the second recess 147 include the inclined regions S2. Since the inclined regions S2 are inclined with respect to the extending direction of the weft 172 and the extending direction of the warp 173 of glass threads 171 as viewed in the Z direction, the glass threads 171 are unlikely to protrude from the inclined regions S2 into the second recess 147. Therefore, as compared with when the entire areas of the side surfaces 149 of the second recess 147 extend along the weft 172 or the warp 173, the amount of glass threads 171 protruding from the side surfaces 149 of the second recess 147 into the second recess 147 can be reduced. Accordingly, interference with accommodation of the optical coupling module 50 by the glass threads 171 protruding into the second recess 147 is inhibited, so that mountability of the optical coupling module 50 is improved. Moreover, presence of the glass threads on the optical path (for example, between the lens 56 and the optical member 60) is inhibited, and transmission of the light L is performed more appropriately.

In the above embodiment, viewed in the Z direction, the outer edge of the second recess 147 has a diamond shape defined by the side surfaces 149. In this case, the second recess 147 having the side surfaces 149 including the inclined regions S2 can be easily formed by a simple constitution.

<First modification example>

The shape of the second recess according to the second embodiment is not limited to the shape described above. For example, as in a first modification example, the in 15 is shown, seen in the direction Z, an outer edge of a second recess 247 has a triangular shape, which is defined by side surfaces 249. With reference to 15 Details of the second recess 247 according to the first modification example will be described.

The second recess 247 has a second bottom portion 248 and the side surfaces 249. A part of the optical coupling module 50 (a part on which the lens 56 is formed, which is in 5 is shown) is placed at the second floor section 248. The second bottom portion 248 extends in the X direction and the Y direction. Viewed in the Z direction, an outer edge of the second bottom portion 248 has a triangular shape.

The side surfaces 249 are surfaces that connect the second floor section 248 and the first floor section 145 to one another. The side surfaces 249 are surfaces that rise from the outer edge of the second floor section 248 towards the first floor section 145. The side surfaces 249 may be parallel to the Z direction or may be inclined. The side surfaces 249 include side surfaces 249a, 249b and 249c. As viewed in the Z direction, each of the side surfaces 249a, 249b and 249c extends along a respective side of the triangular shape shown by the outer edge of the second bottom portion 248. The side surface 249a extends in the X direction as viewed in the Z direction. The side surfaces 249b and 249c are inclined with respect to the X direction and the Y direction as viewed in the Z direction.

That is, in the present modification example, the side surfaces 249b and 249c form the inclined regions S2 which are inclined with respect to the extending direction of the weft thread 172 and the extending direction of the warp thread 173.

The present modification example also exhibits effects like the effects of the second embodiment described above. In addition, in the present modification example, an outer edge of the second recess 247 has a triangular shape defined by the side surfaces 249 as viewed in the Z direction. In this case, the second recess 247 having the side surfaces 249 including the inclined regions S2 can be easily formed by a simple constitution.

<Second modification example>

Additionally, as in a second modification example, the in 16 is shown, an outer edge of a second recess 347 viewed in the Z direction has an oval shape which is defined by a side surface 349. With reference to 16 Details of the second recess 347 according to the second modification example will be described.

The second recess 347 has a second bottom portion 348 and the side surface 349. A part of the optical coupling module 50 (a part in which the lens 56 is formed, which in 5 shown) is placed at the second bottom portion 348. The second bottom portion 348 extends in the X direction and the Y direction. When viewed in the Z direction, an outer edge of the second bottom portion 348 has an oval shape. The major axis of the oval shape extends in the X direction and its minor axis extends in the Y direction.

The side surface 349 is a surface that connects the second bottom portion 348 and the first bottom portion 145 together. The side surface 349 is a surface that rises from the outer edge of the second bottom portion 348 toward the first bottom portion 145. The side surface 349 may be parallel to the Z direction or may be inclined. Viewed in the Z direction, the side surface 349 extends along the side of the oval shape shown by the outer edge of the second bottom portion 348. In the present modification example, regions on the side surface 349 inclined with respect to the X direction and the Y direction (areas excluding tip parts of the oval shape) form the inclined regions S2 which are inclined with respect to the extending direction of the weft thread 172 and the extending direction of the warp thread 173 are. The inclined regions S2 according to the present modification example are curved surfaces that are bent as viewed in the Z direction.

The present modification example also exhibits effects like the effects of the second embodiment described above. In addition, in the present modification example, the inclined regions S2 are curved surfaces that are bent as viewed in the Z direction are. Seen in the Z direction, an outer edge of the second recess 347 has an oval shape that is defined by the side surface 349. In this case, the second recess 347 having the side surface 349 including the inclined regions S2 can be easily formed by a simple constitution.

<Third modification example>

Additionally, as with a third modification example, the in 17 is shown, an outer edge of a second recess 447 viewed in the Z direction has a fan shape which is defined by side surfaces 449. With reference to 17 Details of the second recess 447 according to the third modification example will be described.

The second recess 447 has a second bottom portion 448 and the side surface 449. A part of the optical coupling module 50 (a part in which the lens 56, which is in 5 is shown) is placed at the second floor section 448. The second bottom portion 448 extends in the X direction and the Y direction. Viewed in the Z direction, an outer edge of the second bottom portion 448 has a fan shape.

The side surfaces 449 are surfaces that connect the second floor section 448 and the first floor section 145 to one another. The side surfaces 449 are surfaces that rise from the outer edge of the second floor section 448 towards the first floor section 145. The side surfaces 449 may be parallel to the Z direction or may be inclined. Viewed in the Z direction, the side surfaces 449 extend along the side of the fan shape shown by the outer edge of the second bottom portion 448. The side surfaces 449 include a side surface 449a and a side surface 449b. The side surface 449a extends in the X direction as viewed in the Z direction. Viewed in the Z direction, the side surface 449b is a curved curved surface connecting both end portions of the side surface 449a in the X direction. In the present modification example, areas on the side surface 449b inclined with respect to the X direction and the Y direction (areas excluding the tip part of the side surface 449b and parts intersecting the side surface 449a) form the inclined areas S2 with respect to the extending direction of the weft 172 and the direction of extension of the warp thread 173 are inclined. The inclined regions S2 according to the present modification example are curved surfaces that are bent as viewed in the Z direction.

The present modification example also exhibits effects like the effects of the second embodiment described above. In addition, in the present modification example, the inclined regions S2 are curved surfaces that are bent as viewed in the Z direction. Seen in the Z direction, an outer edge of the second recess 447 has a fan shape that is defined by the side surfaces 449. In this case, the second recess 447 having the side surfaces 449 including the inclined regions S2 can be easily formed by a simple constitution.

Above, the embodiments of the present disclosure have been described in detail; but the present disclosure is not limited to the above embodiments and may be applied to various embodiments. For example, in the above embodiments, the optical modules 30 and 130 have a condition in which the light L emitted from the optical fibers 11 is incident on the optical components 60. However, a condition in which a light emitted from the optical components 60 impinges on the optical fibers 11 can be adopted. At this point, the optical components 60 may be light-emitting components, such as surface emitters (VCSEL or Vertical Cavity Surface Emitting Laser). Light emitted from the optical components 60 may be converted into collimated light (parallel light) by the lenses 56, may be reflected by the mirrors 55, and may then impinge on the optical fibers 11.

The substrates 40 and 140 in the above embodiments may be rectangular substrates having rounded corner portions. In addition, in the above second embodiment, the side surfaces 146 of the first recess 144 may include the inclined regions S1 inclined with respect to the extending direction of the weft thread 172 and the extending direction of the warp thread 173. In this case, an outer edge of the first recess 144 may have a diamond shape, a triangular shape, an oval shape or a fan shape defined by the side surfaces 146 as viewed in the thickness direction of the substrate 140 (direction Z).

List of reference symbols

1

Optical connection cable

10

Optical fiber cable

11

Optical fiber

12

Cable sheath

20

Protective element

21

inner layer

22

outer layer

30, 130

Optical module

40, 140

Substrate

40a, 40b, 40c, 40d, 140a, 140b, 140c, 140d

side surface

41

first main area

41a

grid

42

second main area

43, 143

deepening

43a

Beam section

44, 144

first deepening

45, 145

first floor section

45a

positioning hole

46, 46a, 46b, 146, 146a, 146b

side surface

47, 147, 247, 347, 447

second deepening

48, 148, 248, 348, 448

second floor section

48a

penetration hole

49, 49a, 49b, 149, 149a, 149b, 149c, 149d, 249, 249a, 249b, 249c, 349, 449, 449a, 449b

side surface

50

Optic coupling module

50a

tip surface

50b

side surface

51

groove section

52

upper surface

53

lower surface

55

Mirror

56

lens

60

Optical component

61

integrated circuit

70, 170

Glass fabric

71, 171

Glass threads

72, 172

weft thread

73, 173

warp thread

80, 81, 82

gap

85

adhesive

F

focus

L

Light

S1, S2

inclined area

W1

Width

W2

Width

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2021 [0001]
• JP 128994 [0001]
• JP 2019082508 [0003]

Claims (15)

Optical module, which has: a substrate internally comprising a glass cloth formed of glass threads serving as a weft and a warp, and an outer edge having a rectangular shape, viewed in a thickness direction of the substrate, defined by a pair of first side surfaces in a predetermined direction and a pair of second side surfaces are defined in a direction perpendicular to the predetermined direction; an optical component mounted on the substrate; and an optical coupling module designed to be optically coupled to the optical component, wherein the weft thread is inclined with respect to the first side surfaces and the second side surfaces as viewed in the thickness direction of the substrate, the warp thread is inclined with respect to the first side surfaces and the second side surfaces as viewed in the thickness direction of the substrate, a recess recessed from a first major surface of the substrate toward a second major surface of the substrate to include a bottom portion formed in the substrate and at least a portion of the optical coupling module housed in the recess, and a side surface of the recess includes an inclined region inclined with respect to an extension direction of the weft thread and an extension direction of the warp thread, as viewed in the thickness direction of the substrate. Optical module according to Claim 1 , wherein the recess includes a first recess and a second recess that includes a second bottom portion positioned closer to the second major surface than a first bottom portion of the first recess and includes a smaller opening area than the first recess. Optical module according to Claim 2 , wherein both a side surface of the first recess and a side surface of the second recess comprise the inclined region. Optical module according to Claim 2 or 3 , wherein the optical coupling module includes a lens optically coupled to the optical component, and the lens is housed in the second recess. Optical module, which has: a substrate internally comprising a glass cloth formed of glass threads serving as a weft and a warp, and an outer edge having a rectangular shape, viewed in a thickness direction of the substrate, defined by a pair of first side surfaces in a predetermined direction and a pair of second side surfaces are defined in a direction perpendicular to the predetermined direction; an optical component mounted on the substrate; and an optical coupling module designed to be optically coupled to the optical component, wherein the weft thread extends along the first side surfaces, viewed in the thickness direction of the substrate, the warp thread extends along the second side surfaces, viewed in the thickness direction of the substrate, a recess recessed from a first major surface of the substrate toward a second major surface of the substrate to include a bottom portion formed in the substrate and at least a portion of the optical coupling module housed in the recess, and a side surface of the recess includes an inclined region inclined with respect to an extension direction of the weft thread and an extension direction of the warp thread, as viewed in the thickness direction of the substrate. Optical module according to Claim 5 , wherein the recess includes a first recess and a second recess that includes a second bottom portion positioned closer to the second major surface than a first bottom portion of the first recess and includes a smaller opening area than the first recess. Optical module according to Claim 6 , wherein a side surface of the second recess includes the inclined region, the optical coupling module includes a lens optically coupled to the optical component, and the lens is housed in the second recess. Optical module according to one of the Claims 5 until 7 , wherein the inclined region is a curved surface that is bent as viewed in the thickness direction of the substrate. Optical module according to one of the Claims 5 until 7 , wherein an outer edge of the recess has an oval shape or a fan shape defined by the side surface when viewed in the thickness direction of the substrate. Optical module according to one of the Claims 5 until 7 , wherein an outer edge of the recess has a diamond shape or a triangular shape defined by the side surface as viewed in the thickness direction of the substrate. Optical module according to one of the Claims 1 until 10 , where an angle passing through the inclined area and the extension direction of the weft thread is formed equal to or greater than 10° and equal to or less than 80° as viewed in the thickness direction of the substrate, and an angle formed by the inclined region and the extension direction of the warp thread in which Thickness direction of the substrate is equal to or greater than 10° and equal to or greater than 80°. Optical module according to one of the Claims 1 until 11 , wherein the optical coupling module comprises a holding section for holding end portions of optical fibers that are optically coupled to the optical component via the optical coupling module. Optical module according to one of the Claims 1 until 12 , wherein a penetration hole penetrating the bottom portion to the second main surface is formed in the recess, and the optical component is mounted on the second main surface so that it overlaps the penetration hole as viewed from above the second main surface. An optical module comprising: a substrate internally comprising a glass fabric formed of glass threads serving as weft and warp, and having an outer edge having a rectangular shape as viewed in a thickness direction of the substrate, which is defined by a pair of first side surfaces in a predetermined direction and a pair of second side surfaces in a direction perpendicular to the predetermined direction; a plurality of optical components mounted on the substrate; and a plurality of optical coupling modules configured to be optically coupled to the plurality of respective optical components, wherein the weft thread is inclined with respect to the first side surfaces and the second side surfaces as viewed in the thickness direction of the substrate, the warp thread is inclined with respect to the first side surfaces and the second side surfaces as viewed in the thickness direction of the substrate, a plurality of recesses recessed from a first main surface of the substrate toward a second main surface of the substrate so as to each include a bottom portion are formed in the substrate and each of the plurality of optical coupling modules is accommodated in a respective one of the plurality of recesses, and a side surface of each of the plurality of recesses includes an inclined region inclined with respect to an extension direction of the weft thread and an extension direction of the warp thread as viewed in the thickness direction of the substrate. Optical connection cable, comprising: the optical module according to one of Claims 1 until 14 ; and an optical fiber cable comprising at least one optical fiber, the optical fiber cable being attached to the optical module such that the optical fiber is optically coupled to the optical component via the optical coupling module.

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